Molecular influence in high-strain-rate microparticle impact response of poly(urethane urea) elastomers

Author(s)

Veysset, David Georges; Hsieh, Alex J; Kooi, Steven E; Nelson, Keith Adam

Abstract

The dynamic deformation response of select model poly(urethane urea) elastomers (PUU) at high strain rates is investigated via an all-optical laser-induced projectile impact test (LIPIT). LIPIT measurements allow the direct visualization of the impact of micro-projectiles (silica spheres) on substrates and in-situ characterization, including depth of penetration and the extent of rebound of the micro-projectiles. PUUs are proven to be robust and the silica spheres are observed to rebound from them upon impact. In addition, for PUUs a strong correlation was noted between the coefficient of restitution and the maximum depth of penetration. Also, the coefficient of restitution data is comparable to that of glassy polycarbonate (PC), which is in great contrast to the comparison of the corresponding ambient storage modulus data obtained via dynamic mechanical analysis at 1 Hz. We hypothesize that high-rate deformation-induced glass transition is a plausible molecular relaxation mechanism towards macroscopic, dynamic stiffening/strengthening in PUUs. Keywords: Laser-induced particle impact test (LIPIT); Micro-ballistics; Poly(urethane urea) elastomers; Coefficient of restitution; Depth of penetration; Segmental dynamics; High-rate deformation-induced glass transition

Date issued

2017-06

URI

https://hdl.handle.net/1721.1/123990

Department

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies
Massachusetts Institute of Technology. Department of Chemistry

Journal

Polymer

Publisher

Elsevier BV

Citation

Veysset, David et al. "Molecular influence in high-strain-rate microparticle impact response of poly(urethane urea) elastomers." Polymer 123 (August 2017): 30-38

Version: Author's final manuscript

ISSN

0032-3861